Background

Acute malnutrition to be a major health burden in the world, particularly in the developing world. Acute malnutrition is associated with more than one third of the global disease burden for children. Malnourished children are physically, emotionally and intellectually less productive and suffer more from chronic illnesses and disabilities. The nature, magnitude and determinants of acute malnutrition are determined among the general populations; however, there is a lack of evidence in the nomadic communities.

Methods

A cross-sectional study was conducted to assess the magnitude and factors associated with acute malnutrition among children aged 6–59 months in Hadaleala district, Afar Region. A total of 591 under-five children were included in this study, and subjects were recruited by the multistage cluster sampling technique. Data were collected by a pre-tested questionnaire and a simple anthropometric index so called mid-upper arm circumference (MUAC). The multivariable binary logistic regression analysis was used to identify factors associated with acute malnutrition on the basis of adjusted odds ratio (AOR) with 95% confidence interval (CI) and p < 0.05.

Conclusion

The prevalence of acute malnutrition among children aged 6-59 months was was higher than the national prevalence. The number of children in each household, drinking water sources, latrine availability, hand washing practice before food preparation and child feeding, childhood diarrheal disease, and child vaccination were identified as factors affecting the childhood acute malnutrition in the nomadic community. Protecting drinking water sources from possible contaminants, improving hand washing practices, utilization of latrine, preventing diarrheal diseases and vaccinating children integrated with the access of nutrition education is important to improve nutrition of children of the nomadic people.

Under nutrition continues to be a major health burden in the world, particularly in the developing world [1–3]. Globally, children with moderate and severe acute under nutrition are approximately 60 million and 13 million respectively [1, 2]. Under nutrition is globally the most important risk factor for illness and death, with hundreds of millions of young children particularly affected [4, 5]. It is associated with more than one third of the global disease burden for children [6]. Between 8 to 11 million under-five children die each year globally [2, 7], and more than 35% of these deaths are attributed to under nutrition [3].

Under nutrition among children is a critical problem. Its effects are long lasting [1, 8]. Under nourished children are physically, emotionally and intellectually less productive and suffer more from chronic illnesses and disabilities [9–12]. Malnutrition affects child performance, health, and survival [13, 14]. In the long term, early nutritional deficits are linked to impairments of intellectual performance; work capacity, reproductive outcomes and overall health during adolescence and adulthood [14–18]. The immediate consequences of poor nutrition during the early years include significant morbidity and mortality and delayed mental and motor developments. Malnutrition at the early stages of life can lower child resistance to infections [19]. Moreover, the potential negative impact of child malnutrition goes beyond the individual, affecting society and future generations [20, 21].

In Ethiopia, under nutrition among children is still a common problem. Ethiopia is one of the countries with very high burden of under nutrition. In the country, under nutrition is the underlying cause of 57% of child deaths [22–25].

Under nutrition among children depends on complex interactions of various factors, like socio-demographic [24–30], drinking water quality [26, 28, 29, 31–35], hygiene of complementary foods [24, 28], environmental sanitation [26, 31, 32, 36–38], child co-morbidities [19, 39–44], and child vaccination [45–47]. Though, the nature, magnitude and determinants of under nutrition are determined among the general populations, there is lack of evidence in the nomadic communities. This cross-sectional study was therefore conducted to assess the magnitude and factors associated with acute malnutrition among children aged 6–59 months in Hadaleala district, Afar Region, northeast Ethiopia.

Study design and settings

A community - based cross-sectional study was conducted among the nomadic populations in Hadaleala district, Afar Region, northeast Ethiopia in May, 2015. Hadaleala district is located at 341 km southwest of the regional capital, Semera, and 268 km north of Addis Ababa, the capital city of Ethiopia. It has an area of 1272 km2 divided into 11 rural kebeles (the smallest administrative units in Ethiopia) with a total population of 42,845 as projected for the year 2015. It has 7516 households with an average household size of 5.7 persons per house. Under-five children account for 10.1% (4328) of the total population. As the population lives in a very scattered manner, the average population density is 14 persons/km2. Furthermore, the economy of the district is based on livestock and crop production [48].

Sample size determination

The sample size was determined using the single population proportion formula by considering the following assumptions: p = 10.0% (prevalence of malnutrition among children aged 6–59 months in Bule Hora district, South Ethiopia [49]), 95% confidence interval, and a 4% margin of error (d),

Considering the design effect of 2 and 10% non response rate, the final sample size was 478 mother-child pair.

Sampling procedure

The multistage cluster sampling technique was used to select study participants from the nomadic population. The clusters were villages with defined geographical boundaries. Out of a total of 11 kebeles, 6 were selected by the simple random sampling technique. The 6 selected kebeles were clustered into 39 villages, and 17 villages were selected by the systematic random sampling technique. All the households (591) found in the selected 17 villages with children aged 6–59 months were included in the study. For households which had more than one child each, the younger one was selected for the study.

Data collection tools and procedures

A structured questionnaire and anthropometric measurement were used to collect data. The questionnaire was pre-tested out of the study area in a community which had similar characteristics prior to the actual data collection. Eight diploma graduate nurses and two environmental health officers who were fluent enough in both Amharic and Afarigna (local languages) and working in the district were involved in the data collection process. Training was given for the data collectors and supervisors. The data collectors visited all households in the selected clusters. When the data collectors found the target groups during the visits, they interviewed the mothers about the variables and measured the circumference of the upper arm of the child. Finally, the collected data were checked and corrected by the data collectors immediately after finalizing the questionnaire. Supervisors daily checked the completeness, quality, and consistency of information collected.

Measurement of outcome variable

Childhood malnutrition, the primary outcome variable of this study, is determined by a simple anthropometric index the so called mid-upper arm circumference (MUAC). Nutritional status of children was take as acute malnutrition if MUAC value is lower than 125 mm [50].

Childhood diarrheal disease, one of the predictor variables is defined as having three or more loose or watery stools in 24 h [51, 52]. Household economic status, which was the other predictor variable was calculated by using tropical livestock unit (TLU). Tropical livestock unit was determined by multiplying the number of specific species with the TLU conversion factor assigned to that specific species. Camels, cattle, sheep, goats, horses, mules, asses, and chickens were common in the study area. Generally, TLU was determined as (1.0*Number of camels) + (0.8*Number of horses) + (0.7* Number of mules) + (0.7*Number of cattle) + (0.5*Number of asses) + (0.1*Number of sheep) + (0.1*Number of goats) + (0.01*Number of chickens). Household economic status was determined by comparing the TLU scores with the standard score. A below 5 TLU score indicated that the household was poor. A TLU score of 5 to 12.99 showed the household was medium in economic status, and rich households scored 13 and above TLU [53].

Data management and statistical analysis

Data were entered using the EPI-INFO version 3.5.3 statistical package and exported to SPSS version 20 for further analysis. Cross tabulation was used to describe socioeconomic, environmental sanitation, health, and nutritional characteristics of children. Categorical data were presented as frequency counts or percentages and compared using the Pearson chi-square. Continuous data were summarized as mean or median with ± standard deviation and interquartile range. The univariable binary logistic regression analysis was used to choose variables for the multivariable binary logistic regression analysis, and variables which had less than 0.2 p – values by the univariable analysis were then analyzed by the multivariable binary logistic regression for controlling the possible effects of confounders, and finally, variables which had significant association were identified on the basis of adjusted odds ratio (AOR) with 95% CI and p < 0.05.

Socio-demographic information

A total of 591 mothers - child pair participated in this study with a 100% response rate. More than half, 311 (52.6%) of the mothers were aged 25-34 years. The median age of the mothers was 30 years, and the interquartile range was 25-35 years. Almost all, 577 (97.6%) of the mothers were married at the time of data collection. The great majority, 514 (87.0%) of mothers were illiterate. Almost all, 559 (94.6%) of the mothers were housewives by occupation. Five hundred thirty – seven (90.9%) mothers were Afar by ethnicity. More than half, 339 (57.4%) of the households had more than five family members. Three hundred eighty – two (64.6%) households were economically poor. Two hundred twenty – nine (38.7%) of the children were aged above 35 months. The median age of children was 28 months and the interquartile range (IQR) was 16-40 months. More than half, 338 (57.2%) of the households had only one child aged 6-59 months, and 317 (53.6%) of the children were male (Table 1).

Drinking water and hygiene of complementary foods

Three hundred fifty – four (59.9%) households collected drinking water from unimproved sources and the greater majority, 522 (88.3%) of the water sources were seasonal. Very few, 20 (3.4%) households treated drinking water at home. Cow or goat milk was the commonest, 337 (57.0%) complementary food for the children. Three hundred thirty – three (56.3%) households served uncooked foods for the children, and the greater majority, 551 (93.2%) of the households used unclean utensils to serve foods. Three – forth, 447 (75.6%) of the households fed the children soon after the food is prepared, and the overwhelming majority, 539 (91.2%) used leftover foods. Three hundred twenty - four (54.8%) mothers washed hands with only water (Table 2).

Table 2

Drinking water and hygiene of complementary foods of households in Hadaleala district, Afar region, northeast Ethiopia, April to May, 2015

Environmental variables

Frequency

Percentage

Drinking water sources

Improved

237

40.1

Unimproved

354

59.9

Seasonality of water sources

Permanent

69

11.7

Temporarily

522

88.3

Home based water treatment

Yes

20

3.4

No

571

96.6

Types of complementary foods for the children

Cow or goat milk

337

57.0

Adults’ food

133

22.5

Gruel

112

19.0

Infant formula/Powder milk

9

1.5

Using unclean utensils to serve foods

Yes

551

93.2

No

40

6.8

Serving uncooked food for the children

Yes

333

56.3

No

258

43.7

Feeding children soon after food prepared

Yes

447

75.6

No

144

24.4

Children ate leftover foods

Yes

539

91.2

No

52

8.8

How do you wash your hand

With plain water

324

54.8

With soap

267

45.2

Personal hygiene and environmental sanitation

Nearly one – tenth, 56 (9.5%) of the mothers had good personal hygiene. More than threefold, 483 (81.7%), and 490 (82.9%) of the households practiced open defecation and indiscriminate solid waste disposal respectively. The living environment of 464 (78.5%) households was poor condition, and vector infestation was observed among 483 (81.7%) households. Three hundred thirty (55.8%) households had only one room, and very few, 91 (15.4%) households had cemented or plastered floor (Table 3).

Health condition of mothers and children

Sixty (10.2%) mothers and 172 (29.1%) children had diarrheal disease in the 2 week period prior to the survey. A majority, 416 (70.4%) of the mothers didn’t know the causes of diarrhea. Three hundred twenty – seven (55.3%) and 377 (63.8%) mothers didn’t know that flies and child excreta can cause diarrheal diseases, respectively. The great majority, 477 (80.7%) of the children had ever been vaccinated. However, significant number or proportion, 254 (43.0%) and 418 (70.7%) of the children had no measles and rotavirus vaccination respectively. Four hundred eighty- eight (82.6%) of the children received vitamin A supplementation (Table 4).

Table 4

Health conditions of mothers and children in Hadaleala district, Afar region, northeast Ethiopia, April to May, 2015

Health related information

Frequency

Percentage

Two week history of maternal diarrhea

Yes

60

10.2

No

531

89.8

Childhood diarrhea

Yes

172

29.1

No

419

70.9

Mothers know the causes of diarrheal disease

Yes

175

29.6

No

416

70.4

Mothers know flies transmit diarrheal disease

Yes

264

44.7

No

327

55.3

Mothers know excreta of children can cause disease

Yes

214

36.2

No

377

63.8

Child ever been vaccinated

Yes

477

80.7

No

114

19.3

Measles vaccination

Yes

337

57.0

No

254

43.0

Rota virus vaccination

Yes

173

29.3

No

418

70.7

Vitamin A supplementation

Yes

488

82.6

No

103

17.4

Nutritional status

The MUAC value of 70 children was below 125 mm. Therefore, the prevalence of acute malnutrition among children aged 6 - 59 months in the nomadic population of Hadaleala district, Afar Region was found to be 11.8% (95% CI = 9.3, 14.8%). Female children were more malnourished than males. Out of 70 malnourished children, 42 (60%) females and 28 (40%) males were malnourished respectively. The highest prevalence of acute malnutrition occurred among children aged 12-23 months, which accounted 35 (50%) (Fig. 1).

Fig. 1

Prevalence of acute malnutrition with respect to age of children in Hadaleala district, Afar region, northeast Ethiopia, April to May, 2015

Factors associated with nutritional status

Table 5 presents the results of the binary logistic regression analysis on socioeconomic, water and hygiene of complementary foods, personal hygiene and environmental sanitation, and health related variables. Childhood acute malnutrition was statistically associated with the number of children in the household. Acute malnutrition was 2.49 times more likely to be higher among households with two children compared with households with only one child [AOR = 2.49, 95% CI = (1.06, 5.85)]. Similarly, the likelihood of acute malnutrition was also 12.87 times higher among households with three children compared with households who had one child [AOR = 12.87, 95% CI = (4.04, 41.00)].

Table 5

Factors affecting acute malnutrition among children aged between 6 and 59 months in Hadaleala district, Afar region, northeast Ethiopia, April to May, 2015

Acute malnutrition among children aged 6 - 59 months was associated with drinking water sources, availability of latrine, and hand washing practices. It was 3.78 times more likely to be higher among households that collected drinking water from unprotected sources [AOR = 3.78, 95% CI = (1.07, 13.34)]. The likelihood of childhood acute malnutrition was 5.24 times to be higher among households who had no latrine compared with their counterparts [AOR = 5.24, 95% CI = (1.19, 23.19)]. Children whose mothers washed their hands before food preparation and feeding with soap were less likely to be malnourished. Hand washing with soap before food preparation and child feeding can prevent childhood acute malnutrition by 79% [AOR = 0.21, 95% CI = (0.05, 0.81)].

Childhood acute malnutrition was also statistically associated with the health status of children, like childhood diarrhea and vaccination. Childhood acute malnutrition was 2.72 times more likely to be higher among children who had diarrheal disease [AOR = 2.72, 95% CI = (1.15, 6.40)]. This study indicated that child vaccination has a protective effect on childhood acute malnutrition. Children who ever been vaccinated were 85% less likely to be malnourished, compared with their counterparts [AOR = 0.15, 95% CI = (0.07, 0.31)].

The prevalence of acute malnutrition among children aged 6-59 months was 11.8% (95% CI = 9.3, 14.8%). Childhood acute malnutrition was statistically associated with the number of children in each household, drinking water sources, latrine availability, hand washing practice before food preparation and child feeding, childhood diarrheal disease, and child vaccination. The prevalence of acute malnutrition reported by this study is slightly higher than the national prevalence of acute malnutrion (9%) [54] and findings of various studies conducted in Ethiopia like Bule Hora district, South Ethiopia, 10% [49] and it was also just two-fold higher than the prevalence reported in Aleta Chucko and Aleta Wondo districts, Sidama Zone, South Ethiopia, 5.6% [55]. Whereas, the magnitude of acute malnutrition reported by this study was lower than the findings of studies conducted in Pagak district, South Sudan, 16.7% [56]. The difference in prevalence might be attributed to the difference in the socio- demographic, environmental, and behavioral characteristics of households and the nomadic nature of the population.

This study showed that families who had two or above children aged 6-59 months were more likely to have childhood acute malnutrition than those who had only one child. This probably attributed to less balanced diet intake and accessibility of child healthcare decreased with more number of children per household, especially in low income families [33, 34, 57, 58].

In this study, it was found that acute malnutrition was associated with unprotected drinking water sources, open defecation, and poor hand washing practices of mothers. Different studies also reported that acute malnutrition was associated with drinking water sources [26, 28, 29, 31–35], availability of latrine [26, 31, 32, 36–38] and hand washing practices [36, 59]. This may be so because poor water, hygiene and sanitation condition increase the risk of infections. Infections affect nutrient absorption and compromised nutritional status of children. Evidences show that children who frequently affected by infections have mal-absorption of important nutrients [60–63].

This study indicated that acute malnutrition was associated with child hood diarrheal diseases. Children who had diarrheal disease were more likely to be acutely malnourished as compared with their counter parts. This finding was supported by the findings of other similar studies [24, 28, 33, 36, 38, 64–66]. This may be due to the fact that diarrheal disease due to poor hygiene and lack of sanitation induces a gut disorder called environmental enteropathy (EE) characterized by blunted intestinal villi, increased intestinal permeability; fat and carbohydrate mal-absorption, and increased protein needs [67] that diverts energy from growth towards an ongoing fight against subclinical infection [68–71]. EE is a major cause of post-natal stunting and wasting [71–77].

Child vaccination was also the other statistically associated variable with childhood acute malnutrition. Children who ever vaccinated were less likely to be malnourished compared with their counterparts. This finding is supported by the findings of other similar studies [36, 45–47, 78]. This can be justified as vaccinated children are less likely to be frequently infected with vaccine preventable diseases such as diarrhea and respiratory infections, which are known in depleting nutrients from the body [45, 79, 80].

Finally, this paper determined acute malnutrition using MUAC measurement. It didn’t measure weight and height to determine global malnutrition. This paper also didn’t consider the effect of food security and access to diversified foods on childhood malnutrition. Moreover, the paper didn’t investigate demand side issues and supply side issues of systems failures with respect to poverty alleviation. The authors believed that other studies should be conducted to fill the above identified gaps.

The prevalence of acute malnutrition among children aged 6-59 months was higher than the national prevalence. The number of children in each household, drinking water sources, latrine availability, hand washing practice before food preparation and child feeding, childhood diarrheal disease, and child vaccination were identified as factors affecting the childhood acute malnutrition in the nomadic community. Protecting drinking water sources from possible contaminants, improving hand washing practices, utilization of latrine, preventing diarrheal diseases and vaccinating children integrated with the access of nutrition education is important to improve nutrition of children of the nomadic people.

Acknowledgments

The authors are pleased to acknowledge data collectors, field supervisors, study participants, Hadaleala District Health Office, Afar Regional Health Bureau for their unreserved contributions to the success of this study. The authors would also like to extend their gratitude to Hadaleala district administrators for their facilitation.

Funding

The authors of this study didn’t receive funds from any funding organization. However, University of Gondar had covered questionnaire duplication and data collection fees.

Availability of data and materials

Data will be made available upon requesting the primary author.

Authors’ contributions

All the authors actively participated during conception of the research issue, development of a research proposal, data collection, analysis and interpretation, and writing various parts of the research report. ZG had analyzed the data and had written the manuscript. WW had designed the study protocol and had supervised the quality of data. BDB had revised the study protocol and manuscript. All the authors read and approved the final manuscript.

Ethics approval and consent to participate

Ethical clearance was obtained from the Institutional Review Board of the University of Gondar and an official letter was submitted to the district administrators. There were no risks due to participation in this research project, and the collected data were used only for this research purpose. Verbal informed consent was obtained from the mothers. All information collected from each household was treated with complete confidentiality. During data collection, oral rehydration solution and Zinc tablets with clear instructions were given to children who had diarrhea, and advice was given to mothers to take their children to a nearby health institution for further management diarrhea and malnutrition.

Consent for publication

This manuscript does not contain any individual person’s data.

Competing interests

The authors declare that they have no competing interests.

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Taylor L. From food crisis to nutrition: challenges and possibilities in Ethiopia’s nutrition sector’. Institute of Development Studies. 2012.Google Scholar

Teshome B, Kogi-Makau W, Getahun Z, Taye G. Magnitude and determinants of stunting in children underfive years of age in food surplus region of Ethiopia: the case of west gojam zone. Ethiop J Health Dev. 2009;23(2).Google Scholar

Sisay Z. Magnitude and factors associated with malnutrition of children under five years of age in rural Kebeles of Haramaya, Ethiopia Harar Bull Health Sci Extracts 2012(2011):4.Google Scholar

Sharghi A, Kamran A, Faridan M. Evaluating risk factors for protein-energy malnutrition in children under the age of six years: a case-control study from Iran. Int J General Med. 2011;4:607.Google Scholar

Tariku B, Mulugeta A, Tsadik M, Azene G. Prevalence and risk factors of child malnutrition in community based nutrition program implementing and nonimplementing districts from south East Amhara, Ethiopia. Open Access Library J. 2014;1(03):1.Google Scholar

Morris SS, Cogill B, Uauy R, Maternal, Group CUS. Effective international action against undernutrition: why has it proven so difficult and what can be done to accelerate progress? Lancet. 2008;371(9612):608–21.PubMedView ArticleGoogle Scholar

UNICEF/WHO. Diarrhoea: Why children are still dying and what can be done. The United Nations Children’s Fund/World Health Organization, Geneva, 2009. Available at www.unicef.org/.../Final_Diarrhoea_Report_October_2009_final.pdf. Accessed 18 May 2016.Google Scholar

Jahnke HE. Livestock production systems and livestock development in tropical Africa; Livestock Population in Tropical Africa by Species in Numbers and in Tropical Livestock Units (TLU) 1979. P. 10. www. pdf.usaid.gov/pdf_docs/PNAAN484.pdf. Accessed 10 May 2016.

Bantamen G, Belaynew W, Dube J. Assessment of factors associated with malnutrition among under five years age children at Machakel Woreda, Northwest Ethiopia: a case control study. J Nutr Food Sci. 2014;2014Google Scholar